Duobinary Receiver

1. A method of signal processing, comprising: convening an optical signal into an electrical signal having an amplitude corresponding to optical power of the optical signal; and sampling the electrical signal using a sampling window to generate a bit sequence corresponding to the optical signal, wherein: the sampling window has a width; the electrical signal has a series of waveforms comprising first and second pluralities of waveforms, wherein each waveform of the first plurality represents a binary “0” and each waveform of the second plurality represents a binary “1”; each waveform is integrated over the sampling window width to generate an integration result; the integration result is compared with a decision threshold value to generate a corresponding bit value; the sampling window width is selected to be less than a bit length in the electrical signal in order to reduce contribution of the second plurality of waveforms into integration results corresponding to the first plurality of waveforms; the optical signal is an optical duobinary signal; and the sampling window width is less than about 25% of a bit length.

2. The method of claim 1 , wherein, for each waveform: when the integration result is greater than or equal to the decision threshold value, the bit value is binary “1”; when the integration result is smaller than the decision threshold value, the bit value is binary “0”; and the decision threshold value is selected to correspond to a level different from a mean of space and mark levels in the electrical signal in order to reduce contribution of spontaneous bit noise and thermal noise into the integration results corresponding to the first and second pluralities of waveforms.

3. The method of claim 1 , wherein the width of the sampling window is selected based on an eye diagram of the optical signal.

4. The method of claim 1 , further comprising: generating a first clock signal based on the electrical signal; multiplying a frequency of the first clock signal to generate a second clock signal; and selecting the width of the sampling window using the second clock signal.

5. The method of claim 4 , comprising aligning the sampling window with respect to the waveforms based on the second clock signal.

6. The method of claim 1 , wherein the sampling window width is selected based on duty cycle corresponding to the second plurality of waveforms.

7. The method of claim 6 , wherein the duty cycle is greater than one.

8. The method of claim 1 , wherein the sampling window width is about 10% of a bit length.

9. An optical receiver, comprising: a signal converter adapted to convert an optical signal into an electrical signal having an amplitude corresponding to optical power of the optical signal; and a decoder coupled to the signal converter and adapted to (i) sample the electrical signal using a sampling window and (ii) generate a bit sequence corresponding to the optical signal, wherein: the sampling window has a width; the electrical signal has a series of waveforms comprising first and second pluralities of waveforms, wherein each waveform of the first plurality represents a binary “0” and each waveform of the second plurality represents a binary “1” ; the decoder is adapted to: integrate each waveform over the sampling window width to generate an integration result; compare the integration result with a decision threshold value to generate a corresponding bit value; and select the sampling window width to be less than a bit length in the electrical signal in order to reduce contribution of the second plurality of waveforms into integration results corresponding to the first plurality of waveforms; the optical signal is an optical duobinary signal; and the sampling window width is less than about 25% of a bit length.

10. The receiver of claim 9 , wherein, for each waveform: when the integration result is greater than or equal to the decision threshold value, the bit value is binary “1”; when the integration result is smaller than the decision threshold value, the bit value is binary “0”; and the decision threshold value is selected to correspond to a level different from a mean of space and mark levels in the electrical signal in order to reduce contribution of spontaneous bit noise and thermal noise into the integration results corresponding to the first and second pluralities of waveforms.

11. The receiver of claim 9 , wherein the sampling window width is selected based on an eye diagram of the optical signal.

12. The receiver of claim 9 , further comprising: a clock recovery circuit coupled to the signal converter and adapted to generate a first clock signal based on the electrical signal; and a clock multiplier coupled between the clock recovery circuit and the decoder and adapted to multiply a frequency of the first clock signal to generate a second clock signal, wherein: the decoder is adapted to select the sampling window width based on the second clock signal.

13. The receiver of claim 12 , wherein the decoder is adapted to align the sampling window with respect to the waveforms based on the second clock signal.

14. The receiver of claim 9 , wherein the sampling window width is selected based on duty cycle corresponding to the second plurality of waveforms.

15. The receiver of claim 14 , wherein the duty cycle is greater than one.

16. The receiver of claim 9 , wherein the sampling window width is about 10% of a bit length.

17. An optical communication system, comprising an optical transmitter and an optical receiver coupled via a transmission link, wherein the optical receiver comprises: a signal converter adapted to convert an optical signal received from the transmitter via the transmission link into an electrical signal having an amplitude corresponding to optical power of the optical signal; and a decoder coupled to the signal converter and adapted to (i) sample the electrical signal using a sampling window and (ii) generate a bit sequence corresponding to the optical signal, wherein: the sampling window has a width; the electrical signal has a series of waveforms comprising first and second pluralities of waveforms, wherein each waveform of the first plurality represents a binary “0” and each waveform of the second plurality represents a binary “1”; the decoder is adapted to: integrate each waveform over the sampling window width to generate an integration result; compare the integration result with a decision threshold value to generate a corresponding bit value; and select the sampling window width to be less than a bit length in the electrical signal in order to reduce contribution of the second plurality of waveforms into integration results corresponding to the first plurality of waveforms; the optical signal is an optical duobinary signal; and the sampling window width is less than about 25% of a bit length.

18. The system of claim 17 , wherein: when the integration result is greater than or equal to the decision threshold value, the bit value is binary “1”; when the integration result is smaller than the decision threshold value, the bit value is binary “0”; and the decision threshold value is selected to correspond to a level different from a mean of space and mark levels in the electrical signal in order to reduce contribution of spontaneous bit noise and thermal noise into the integration results corresponding to the first and second pluralities of waveforms.

19. An optical receiver, comprising: means for converting an optical signal into an electrical signal having an amplitude corresponding to optical power of the optical signal; and means for sampling the electrical signal using a sampling window to generate a bit sequence corresponding to the optical signal, wherein: the sampling window has a width: the electrical signal has a series of waveforms comprising first and second pluralities of waveforms, wherein each waveform of the first plurality represents a binary “0” and each waveform of the second plurality represents a binary “1”; each waveform is integrated over the sampling window width to generate an integration result; the integration result is compared with a decision threshold value to generate a corresponding bit value; and the sampling window width is selected to be less than a bit length in the electrical signal in order to reduce contribution of the second plurality of waveforms into integration results corresponding to the first plurality of waveforms; the optical signal is an optical duobinary signal; and the sampling window width is less than about 25% of a bit length.